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Final Report
Development of soil disinfestation systems for production of certified strawberry runners
Victorian Strawberry Industry Certification Authority
Project Number: BS13000
BS13000
This project has been funded by Horticulture Innovation Australia Limited using funds from the Australian Government and the following sources: Toolangi Certified Strawberry Runner Growers Co-operative Strawberry (R& D Levy) Victorian Strawberry Industry
Certification AuthorityHorticulture Innovation Australia Limited (Hort Innovation) makes no representations and expressly disclaims all warranties (to the extent permitted by law) about the accuracy, completeness, or currency of information in Development of soil disinfestation systems for production of certified strawberry runners.
Reliance on any information provided by Hort Innovation is entirely at your own risk. Hort Innovation is not responsible for, and will not be liable for, any loss, damage, claim, expense, cost (including legal costs) or other liability arising in any way (including from Hort Innovation or any other person’s negligence or otherwise) from your use or non-use of Development of soil disinfestation systems for production of certified strawberry runners, or from reliance on information contained in the material or that Hort Innovation provides to you by any other means. ISBN 978 0 7341 3962 7
Published and distributed by: Horticulture Innovation Australia Limited Level 8, 1 Chifley Square Sydney NSW 2000 Tel: (02) 8295 2300 Fax: (02) 8295 2399 © Copyright 2016
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Contents
1. Summary ...................................................................................................................................... 3
2. Keywords ...................................................................................................................................... 5
3. Introduction .................................................................................................................................. 6
4. Methodology ................................................................................................................................. 8
5. Outputs ...................................................................................................................................... 14
6. Outcomes / Results ..................................................................................................................... 19
7. Evaluation and Discussion ............................................................................................................ 39
8. Recommendations ....................................................................................................................... 45
9. Scientific Refereed Publications .................................................................................................... 48
10. Intellectual Property/Commercialisation ...................................................................................... 49
11. References ................................................................................................................................ 50
12. Acknowledgements .................................................................................................................... 52
13. Appendix ................................................................................................................................... 53
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1. Summary
The withdrawal of the soil fumigant methyl bromide (MB) is currently threatening the integrity of the
Victorian Runner Certification Scheme and the viability of the Australian strawberry industry. The use of
mixtures of MB and chloropicrin (Pic) for soil disinfestation in the runner industry has been world’s best
practice, but non-quarantine uses are being phased-out under the Montreal Protocol. Soil disinfestation
with MB/Pic has enabled the production of healthy runners and protected the strawberry fruit industry
against the spread of soil-borne pathogens, weeds, and pests. It has therefore secured the productivity
and viability of the industry.
Currently available substitute fumigants to MB/Pic (e.g. 1,3-dichloropropene (1,3-D)/Pic, 65:35) do not
work in the unique soil type (high clay and organic matter) and environment (cold temperatures) at
Toolangi, Victoria, which is the major district for production of runners in Australia. The soils in this
region retain residues of substitute fumigants, which can kill strawberry plants (crop phytotoxicity).
Without an effective substitute or access to MB in the runner industry, evidence suggests that
strawberry fruit yields across Australia will decrease by 15%, and plant health will decline.
This project aimed to develop soil-less and soil disinfestation systems to replace MB/Pic for the
production of Certified strawberry runners.
Partial budget analysis showed that the use of soil-less substrates for runner production in Victoria
would increase the cost of transplants by 6-fold, compared with production in MB/Pic-treated soil.
Research showed that hydroponic systems increased the efficiency of transplant production, compared
with soil-less substrates. However, fruit yields from transplants produced using hydroponics and soil-
less media (plug plants) were highly variable across Australia (40% less to 22% more), and require
further research on their physiology before being a technically or economically feasible method of
production.
Research identified strategies for the runner industry to reduce the risk of crop phytotoxicity from
substitute fumigants. This includes the use of formulations of 1,3-D/Pic containing low concentrations of
1,3-D (i.e. 1,3-D/Pic (20:80)), and new substitute fumigants (e.g. ethanedinitrile (EDN) and dimethyl
disulphide/Pic) with short residual times in soils at Toolangi, Victoria. Co-application of these substitute
fumigants with specific pre- and post-emergent herbicides (isoxaben, phenmedipham and fluazifop-p)
improved weed control, without affecting runner yields. Data from this project supported the
registration of a new formulation of 1,3-D/Pic (20:80) (TriForm 80®). However, other products (except
fluazifop-p) are still undergoing evaluation for registration in Australia, and are not currently available to
runner growers.
None of the substitute fumigants tested provided the same level of control of soil-borne pathogens as
MB/Pic, particularly at greater soil depths. Runners grown in soils treated with substitute fumigants in
the nursery, produced 16% less fruit and had higher incidences of some diseases (Pythium rot) in the
fruit industry, compared with runners grown in the nursery in soils treated with MB/Pic. Further
research is urgently needed to improve pathogen control using key substitute fumigants, including
evaluation of: deeper application, different fumigant formulations, use of totally impermeable films,
higher application rates, new fumigants, and integration with biofumigation rotations.
4
The runner industry needs to consider making further applications to the United Nations for critical-use
exemptions to retain MB, while research and registration of key substitute fumigants continues. In
addition, governments need to consider whether the current use of MB in the runner industry to control
and prevent the spread of major soil-borne pathogens around Australia qualifies as a quarantine use,
which is exempt from phase-out. These strategies would enable time to develop viable substitutes to
MB, and protect the fruit industry from expected losses of $60 M p.a. without MB or a suitable substitute
in the runner industry.
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2. Keywords
Strawberry; Strawberry nursery; Fumigant; Methyl Bromide; Herbicide; Fungicide; Soil-less Production;
Plug Plant; Critical-use Exemption; Quarantine.
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3. Introduction
Certified planting material (runners) derived from pathogen-tested (PT) stock underpins the national
strawberry fruit industry valued at $450 M p.a. (Strawberries Australia, 2012). The Victorian runner
industry produces about 70% (60 million runners) of the planting material used by the Australian
strawberry fruit industry. The initiation of the Victorian Strawberry Runner Certification Scheme in the
1960s immediately quadrupled fruit yields and allowed the strawberry fruit industry to develop and
flourish (Anon., 2010). High health planting material based on the PT concept remains the cornerstone
of a productive and profitable national fruit industry.
Soil disinfestation is the process of reducing or eliminating pathogens, weeds and pests in soil prior to
planting crops. It is the key strategy used in the Certification Scheme to safeguard against the build up
of soil-borne pests, and their possible spread to the fruit industry in runners. The use of mixtures of
methyl bromide (MB) and chloropicrin (Pic) to disinfest soil for runner production was world’s best-
practice, but non-quarantine uses of MB are being phased-out under the Montreal Protocol. This is
because MB is reported to be an ozone-depleting product (Porter et al., 2009). The withdrawal of MB is
threatening the integrity of the Certification Scheme, and the viability of the Australian strawberry
industry.
In the USA, federal legislation has classified soil disinfestation with MB/Pic in the runner industry as a
quarantine use, which is exempt from phase-out. This is to prevent the possible distribution of
nematode pathogens across county, state, and international borders. The classification of MB as a
quarantine treatment has secured unlimited use of the product in the runner industry in the USA,
safeguarded the high-health status of its fruit industry, and allowed industry expansion. Its use in the
USA also supports the health of runners exported to some European countries. In Australia, soil
disinfestation with MB/Pic in the runner industry is not currently classified as a quarantine use and is
therefore not exempt from phase-out.
Over the last 20 years, extensive research programs have successfully identified and developed
substitute fumigants, such as 1,3-dichloropropene (1,3-D) and Pic, to replace the use of MB/Pic for soil
disinfestation in Australian horticulture, including the strawberry fruit industry (BS98004, BS01004,
BS04009, BS07014). These substitutes, however, did not work effectively in the strawberry runner
industry. The problem related to the unique soil type (high clay and organic matter content) and
environment (cold temperatures) at Toolangi, Victoria, which is the major district for production of
runners in Australia. In commercial trials, the soils at Toolangi consistently retained residues of
substitute fumigants and caused crop losses of up to 40% due to phytotoxicity, and poor control of soil-
borne pathogens, weeds, and pests. The seriousness of the issue is highlighted by the fact that the
previous runner industry at Kempton, Tasmania closed down in 2014 because the substitute fumigants it
adopted failed to control soil-borne pests to adequate levels (P. Bignell, personal communication).
Without access to MB or an effective substitute, evidence suggested that supply of runners to the fruit
industry in Australia would fall by up to 30%, fruit yields would decrease by 15% (worth $30-60 M p.a.),
and plant health would decline (BS01004).
To overcome this, the runner industry has applied annually for critical-use-exemptions (CUEs) from the
United Nations (UN) to retain the use of small quantities of MB (29.76 tonnes) for soil disinfestation and
production of Certified runners, until a suitable substitute is found. Extensive research that showed
there were no technically or economically feasible substitutes (BS98004, BS01004, BS04009, BS07014)
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provided the basis for these applications. CUEs, however, are only a short-term solution for the runner
industry, and it is unlikely that the UN will grant them for long periods into the future.
The aim of this project was to identify substitute treatments to MB/Pic for soil disinfestation that meet
Certification and biosecurity standards for strawberry runners. The approach was to: (1) develop
integrated treatments from existing and new chemistries (fumigants, biofumigants, herbicides,
fungicides) that disinfest soils at Toolangi, Victoria without causing runner crop losses from
phytotoxicity, and (2) evaluate soil-less systems for runner production that avoid the need for soil
disinfestation.
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4. Methodology
4.1 General Approach:
This project conducted field trials and analysis in the Victorian strawberry nursery industry, and
evaluation trials in the Victorian and Western Australian strawberry fruit industries on soil disinfestation
and soil-less systems to replace the use of MB/Pic for runner production. Field days were regularly held
at trial sites to communicate research outcomes to growers.
A steering group was formed at the beginning of the project to guide the direction of the research and
communication activities, and ensure they remained relevant to industry and government needs. This
approach was necessary to allow flexibility in response to directions requested by the United Nation’s MB
Technical Options Committee (MBTOC), and to ensure that research focused on practical methods
suitable for rapid adoption by industry. The steering group met annually, and consisted of
representatives from the strawberry runner and fruit industries, Victorian Strawberry Industry
Certification Authority, Commonwealth Department of the Environment, commercial fumigators,
Victorian Department of Primary Industries, La Trobe University, and project researchers. The group
reviewed progress within the project and developed annual work plans, which were then submitted to
HIA Limited for endorsement.
4.2 Development of Integrated Soil Disinfestation Systems:
4.2.1 Small-Scale Trials
Six field trials were conducted at Toolangi, Victoria from 2013 to 2017 investigating the effects of 102
different combinations, rates, and application methods of fumigants (Table 1), and biofumigant, pre-
and post-emergent herbicides, and fungicides (Table 2) on soil disinfestation and strawberry runner
production. The selection of these treatment combinations was based on reports of their successful use
in strawberries in the literature (e.g. Fennimore and Richard, 1999; Jennings et al., 2006) and those
used overseas (as seen on study tours, see below). Field trials were conducted as randomised split-plot
designs with four blocks. Fumigant treatments formed the main plots (30-70 m × 2.7 m), and
biofumigant, herbicide and fungicide treatments formed the split-plots (10-20 m × 2.7 m). Untreated
and MB/Pic-treated (500 kg/ha) soils were used as the controls. Data were analysed using ANOVA as
performed on Genstat v.16. Appropriate data transformations were made when necessary to restore
normality of distribution and/or homogeneity of variance.
Fumigant treatments were applied to clay ferrosol soils under barrier films in September/October using
the methods described in Table 1. Licensed contractors applied all fumigants in the trials. Barrier films
were removed after 1-2 weeks, and the soil allowed to air for 4-8 weeks after treatment (to meet
recommended plant-back times). Single rows of strawberry mother plants were transplanted along the
middle of the plots, spaced 50 cm apart. Herbicides and fungicides were applied using a knapsack
sprayer (Solo® 12 volt) as described in Table 2. All other agronomic procedures followed standard
industry practices. Runners were harvested in May/June the following year. The strawberry cultivars
used in the trials included Albion, Monterey, San Andreas, Gaviota and Fortuna.
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Table 1. List of fumigant and barrier film treatments investigated in different combinations in trials in
the strawberry runner industry at Toolangi, Victoria from 2013-2017.
10
Table 2. List of biofumigant, herbicide and fungicide treatments investigated in different combinations
in trials in the strawberry runner industry at Toolangi, Victoria from 2013-2016.
11
In 2014/15, a separate trial was established using the modelling method described by Mattner et al.
(2003) to determine plant-back times (period required between fumigation and planting) of key
substitute fumigants (1,3-D/Pic 35:65, 40:60 and 20:80, Pic, Pic + MS, DMDS, and DMDS/Pic) compared
with MB/Pic, and their risk of causing crop losses due to phytotoxicity. Following fumigation (see
above), mother plants were transplanted into soil at 2, 4, 6, 8, or 12 weeks after treatment. The trial
was conducted as a randomised split-plot design with four blocks. Fumigant treatments formed the
main plots and plant-back treatments formed the split-plots. The strawberry cultivar used was Gaviota,
because it has previously shown sensitivity to fumigant residues in soil (Mattner et al., 2003).
Parameters assessed in the trials were measured using established techniques (BS07014), and included:
(1) fumigant concentration and distribution in soil (using photo-ionisation detection (MiniRae®) and/or
detector tubes (Gastec®), Van Wambeke, 2010); (2) survival of buried inoculum (sclerotia or inoculated
seed) of strawberry pathogens or weed seeds; (3) pathogen concentration in soil (qPCR for a suite of
strawberry pathogens conducted by the South Australian Research and Development Institute (Pythium
spp. clade I & F, Verticillium dahliae, Meloidogyne hapla, Pratylenchus penetrans, and Macrophomina
phaseolina); (4) weed emergence (number and identity per m²); (5) mother plant establishment (length
of primary stolon, leaf number, leaf area at two months after planting); (6) crown and root
diseases/syndromes in harvested runners (e.g. incidence of Phytophthora crown rot and severity of
black roots); and (7) runner yield (runners/m²) and quality (crown diameter).
4.2.2 Commercial Trials
From 2013-2017, the best soil disinfestation systems (Pic and 1,3-D/Pic (60:40) and (20:80) + isoxaben)
identified in small-scale trials (see above) were investigated in five commercial trials in the runner
industry, compared with MB/Pic. Plot areas were c. 0.5 – 1 ha per treatment and planted with the same
strawberry cultivar (either Palomar, Monterey, Albion, or Fortuna). Similar parameters were measured
in commercial trials to those described above. In addition, runners harvested from different treatments
were planted in the strawberry fruit industry at Millgrove, Victoria and Wanneroo, Western Australia.
These trials were set up as randomised complete block designs, with four blocks. There were 20-32
plants per plot. Yields of fruit were assessed through the season, and revenue from fruit calculated
using national market data (supplied by FreshLogic).
4.3 Soil-less Systems for Production of Strawberry Runners:
4.3.1 Feasibility Analyses
A literature review and partial-budget analysis were conducted to investigate the technical and economic
feasibility of soil-less systems for production of runners, which avoid the need for soil disinfestation. The
partial-budget analysis followed the methods established by the UN’s Technical and Economic
Assessment Panel (TEAP) for the economic analysis of substitutes to MB (UNEP, 2013). The analysis
calculated the projected price of bare-rooted runners grown in substrate bins for strawberry fruit
growers, compared with those grown in MB/Pic-treated soils. TEAP states that ‘alternatives leading to
decreases in gross margins of around 15 to 20 percent or more are not financially feasible’, and this
formed the benchmark for assessing the economics of the system. The literature review and partial-
budget analysis were published as peer-reviewed papers (Mattner et al., 2014; 2016, see ‘Scientific
Refereed Publications’).
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4.3.2 Study Tours
This project organised and conducted study tours of the Japanese (2013), European (2014) and South
African (2015) runner industries, which have partially adopted soil-less production systems.
Representatives of the Victorian runner industry and VSICA participated in the study tours. Outcomes
from the tours were communicated to the runner industry in technical reports, grower presentations,
and the literature review (see above). Design aspects of the soil-less systems observed overseas were
incorporated and evaluated in research in Australia (see below).
4.3.3 Research on Soil-less Systems
Three trials were conducted at Toolangi, Victoria in and near a commercial screenhouse facility from
2013 - 2016. The screenhouse was 800 m2 with a concrete floor, double annex door entrances, single-
skin plastic film on the roof, and Biomesh (opening size of 0.24 mm × 0.75 mm) on the sides for natural
ventilation. Three soil-less production systems were evaluated for production of strawberry transplants:
(1) hydroponics outdoors (2) hydroponics in the screenhouse, and (3) production in bins containing
substrate in the screenhouse. Yields of transplants in the soil-less systems were compared with the
standard production method in the field in a soil fumigated with MB/Pic (500 kg/ha). All plants in soil-
less treatments were fertigated with a standard hydroponics blend and drip irrigated using established
practices (BS06029, BS09019). The cultivars used in the trial were San Andreas, Albion, and Monterey
(day-neutral cultivars), and Festival and Camarosa (short-day cultivars). The trials were planted in
September / October and harvested in April / May.
The hydroponic system consisted of polyethylene bags (100 cm × 20 cm × 15 cm) containing a soil-less
mix (Coco-peat, pH of 5.7 – 6.5) mounted on raised gutters (2.1 m). Strawberry mother plants
(produced by vegetative propagation) were planted in a single row 20 cm apart in the bags. Strawberry
stolons produced from the mother plants were allowed to hang down from the raised gutters. At
harvest, tips (stolon nodes) were planted into seedling containers (166 cm3 cells) filled with substrate
(Debco Seed and Cutting Mix). Seedlings were misted for 4-weeks in a screenhouse to produce
strawberry plug plants.
The substrate bin treatment consisted of plastic bins (1 m 1 m 0.5 m) filled with a soil-less mix
(70:30 coir/composted bark mixture). A single mother plant (produced by vegetative propagation) was
planted in each bin. Nodes produced on stolons were pinned into the substrate to produce bare-rooted
runners.
Yields of transplants (plug plants or bare-rooted runners, depending on the treatment) were expressed
on an area of production basis (transplants/m2). There were 10 replicates for each treatment. Results
were compared using Student’s t-test, and 95% confidence intervals calculated using Genstat v.16.
The performance of plug plants was evaluated in the Victorian nursery industry at Toolangi, Victoria and
the strawberry fruit industry at Millgrove, Victoria and Wanneroo, Western Australia, compared with
bare-rooted runners produced in MB/Pic-treated soil. The trials were conducted as randomised
complete block or split-plot designs, with four blocks. Runner or fruit yields were determined through
the season.
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4.4 Technology Transfer:
A technology transfer program was conducted to communicate project outcomes to a diverse audience.
4.4.1 Government Agencies
Critical-use nominations for MB were prepared annually (three in total) for the runner industry based on
research in this project, and delivered to the Commonwealth Department of the Environment and the
United Nations for consideration. An analytical report was also prepared for industry to allow an
assessment on the quarantine status of MB use in the runner industry by state and national biosecurity
agencies.
4.4.2 Strawberry Growers
Field demonstrations and workshops were conducted annually for runner growers at trial sites.
Additionally, growers were informed of project outcomes through articles in industry magazines and
newsletters (see ‘Outputs’). At the completion of the project, a best-practice guide on soil disinfestation
was produced and distributed to all Victorian runner growers (Appendix I).
A small desktop study was conducted to explore the possibility of moving the runner industry from
Toolangi to other areas in Australia that may have soil types more suitable for the use of substitute
fumigants. This analysis considered previous research trials on runners in different regions, data on soil
type, late summer / autumn temperatures for chill, altitude, and plant protection regulations.
Methodology also included personal communication and meetings with agronomists and government
scientists in different regions of Australia, and with runner growers themselves. The analysis did not
consider the economics and social impact of moving the runner industry to other regions of Australia.
The analysis was delivered to the Victorian runner industry.
4.4.3 Chemical Companies
Reports on the technical efficacy of individual products were prepared and used by chemical companies
to support the possible registration of these products (see ‘Outputs’). Trial inspections were held for
representatives from chemical companies.
4.4.4 Scientific Community
Scientific outcomes from this project were published in peer reviewed papers (see ‘Scientific Refereed
Publications’) and conference papers (see ‘Outputs’).
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5. Outputs
5.1 Field Days, Workshops, Demonstrations, Meetings and Presentations:
Merriman PR et al. (2013). 10 July 2013. Critical use exemptions and MB alternatives (field day with
representatives of the Department of the Environment, and strawberry runner and fruit growers).
Toolangi Research Farm, Victoria. 10 July 2013. 17 Attendees.
Milinkovic M. et al. (2013). MB Research Update and Soil-less Systems of Runner Production (oral
presentations). Toolangi Research Farm, Victoria. 13 November 2013. 21 Attendees.
Weda G. et al. (2013). Guest Strawberry Fruit Grower Talk: Dr Doug Shaw UC Davis, ‘The Importance of
Methyl Bromide for Strawberry Production’ (field day and workshop). Millgrove, Victoria. 29 November,
2013. 41 Attendees.
Mattner SW (2014). Drip fumigation with alternative fumigants in the strawberry fruit industry (oral
presentation at field day translated into Vietnamese). Strawberry Growers Association of Western
Australia, Wanneroo, Western Australia. 27 February 2014. 29 Attendees.
Mattner SW et al. (2014). (1) European systems of runner production, (2) North Carolina program on
MB alternatives (Dr Robert Welker, guest speaker), (3) MB research update, (4) Field trial inspection
(field day and farm walk). Toolangi Research Farm. 10 March 2014. 8 Attendees.
Merriman PR et al. (2014). Meeting with the Victorian Minister of Agriculture. Presentation, ‘MB and
quarantine in the strawberry runner industry’, and trial inspection. Toolangi Research Farm, Victoria.
20 March 2014. 9 Attendees.
Mattner SW et al. (2014). Three UN Bilateral Meetings between representatives of VSICA, the Victorian
strawberry runner industry, Commonwealth Department of the Environment and (1) the UNs Methyl
Bromide Technical Options Committee, (2) the European Community Party to the Montreal Protocol, and
(3) the Swiss Party to the Montreal Protocol. Meeting of the Parties to the Montreal Protocol, Paris.
15 July 2014. 6 – 15 Attendees.
Mattner SW et al. (2014). Project Co-ordination Group Meeting (meeting). Toolangi Research Farm,
Victoria. 19 September 2014. 10 Attendees.
Merriman PR et al. (2014). Meeting between representatives of VSICA, the Victorian strawberry runner
industry, and Commonwealth Department of the Environment on (1) outcomes from the study tour of
European strawberry nursery industries, and (2) the possible use of MB under a quarantine category in
the Australian runner industry. Department of the Environment, Canberra, ACT. 21 October 2014.
7 Attendees.
Mattner SW, Porter IJ, et al. (2014). Update on international regulatory issues with MB, outcomes from
the study tour of Europe (oral presentations). Toolangi Research Farm, Victoria. 27 November, 2014.
9 Attendees.
Milinkovic M et al. (2014). Soil-less systems of runner production (field demonstration). Toolangi
Research Farm, Victoria. 27 November 2014. 9 Attendees.
15
Milinkovic M et al. (2015). Soil-less production of strawberry runners (oral presentation). Toolangi
Research Station, Toolangi, Victoria. 20 July, 2015. 7 Attendees.
Mattner SW et al. (2015). Project Co-ordination Group Meeting (meeting). Tullamarine Airport, Victoria.
16 September 2015. 10 Attendees.
Mattner SW et al. (2015). Arkema Industry Tour (on-farm meeting and trial inspection). Toolangi, and
Yarra Valley, Victoria. 23 October 2015. 8 Attendees.
Mattner SW et al. (2015). BOC Industry Tour (on-farm meeting and trial inspection). Toolangi, Victoria.
26 October 2015. 6 Attendees.
Mattner SW et al. (2015). Update on MB alternatives (oral presentation). Toolangi Research Farm,
Toolangi, Victoria. 24 November 2015. 15 Attendees.
Milinkovic M et al. (2015). Soil-less Production of Strawberry Runners (oral presentation). Toolangi
Research Farm, Toolangi, Victoria. 24 November 2015. 15 Attendees
Milinkovic M. et al. (2015). Demonstration of Soil-less Production of Strawberry Runners (field
demonstration). Toolangi Research Farm, Toolangi, Victoria. 24 November 2015. 15 Attendees.
Mattner SW et al. (2015). Integrated weed control with herbicides and fumigants (oral presentation).
Toolangi Research Farm, Toolangi, Victoria. 9 December 2015. 10 Attendees.
Greenhalgh FC et al. (2016). Certified Strawberry Runner Production (field day). Australasian Plant
Pathology Society Field Day. Toolangi Research Station, Toolangi, Victoria. 16 February 2016.
33 Attendees.
Mattner SW et al. (2016). Performance of Plug Plants in the Strawberry Fruit Industry (field
demonstration). Millgrove, Victoria. 19 February 2016. 8 Attendees.
Mattner SW et al. (2016). MB Alternatives Trials Farm Walk (field day). Toolangi, Victoria. 4 March
2016. 16 Attendees.
Milinkovic M, Barel M., et al. (2016). Grower meeting on steam disinfestation of soil and substrate (oral
presentation and demonstration). Toolangi, Victoria. 12 July, 2016. 9 Attendees.
Mattner SW et al. (2016). Department of the Environment / Runner Grower Field Inspections of MB
Alternatives Trials (field day). Toolangi & Yarra Valley, Victoria. 11 March 2016. 11 Attendees.
Mattner SW et al. (2016). Three UN Bilateral Meetings between representatives of VSICA, the Victorian
strawberry runner industry, Commonwealth Department of the Environment and (1) the UNs Methyl
Bromide Technical Options Committee, (2) the European Community Party to the Montreal Protocol, and
(3) the Swiss Party to the Montreal Protocol. Meeting of the Parties to the Montreal Protocol, Vienna.
18-20 July 2016. 6 – 8 Attendees.
Mattner et al. (2016). Status of critical-use exemptions and substitutes for MB (oral presentation).
Toolangi, Victoria. 29 November, 2016. 16 Attendees.
Milinkovic et al. (2016). Field demonstration of soil-less techniques for strawberry runner production
(field walk). Toolangi, Victoria. 29 November, 2016. 16 Attendees.
16
Mattner SW et al. (2016). Integrated use of substitute fumigants and herbicides for strawberry runner
production at Toolangi (oral presentation). TCSRGC AGM, Toolangi, Victoria. 15 December, 2016. 13
Attendees.
Brodie GI, Mattner SW et al. (2016). In-field demonstration of soil disinfestation with a prototype
microwave system. Toolangi, Victoria. 21 December, 2016. 15 Attendees.
Mattner SW et al. (2016). Draslovka meeting on EDN registration in Australia. Melbourne, Victoria.
28 December, 2016. 6 Attendees.
Mattner SW et al. (2016) TriCal Industry Tour (on-farm meetings). Toolangi and Yarra Valley, Victoria.
13 March, 2017. 7 Attendees.
Mattner SW et al. (2016) Arkema Industry Tour (on-farm meetings and trial inspections). Toolangi and
Yarra Valley, Victoria. 28-29 March, 2017. 12 Attendees.
5.2 Conference Presentations / Papers:
Mattner S.W., 2013. Prospective uses of seed meals for soil disinfestation in horticulture. Asian Pacific
Seed Association Congress. Kobe, Japan, 20 November 2013. Keynote Address.
Mattner SW, Milinkovic M., et al., 2016. Addressing critical challenges in the phase-out of methyl bromide
in the Australian strawberry industry. Abstract for the International Strawberry Symposium, Quebec,
Canada (accepted).
Mattner S.W., Milinkovic M., et al., 2014. Critical challenges for the phase-out of methyl bromide in the
Australian strawberry industry: Economics of soil-less production of transplants. Seventh International
Symposium on Chemical and Non-Chemical Soil and Substrate Disinfestation. Torino, Italy, July 13-17.
Mattner S.W., Milinkovic M., et al., 2015. Efficacy and plant-back of dimethyl disulphide in the Australian
strawberry industry. In Proceedings of the International Methyl Bromide Alternative Outreach Conference,
San Diego, November 2015.
Mattner S.W., Milinkovic M., et al., 2015. Evaluation of soil-less systems for strawberry transplant
production. International Convention & Exhibition on Soil-less Culture: Hydroponics & Aeroponics. Gold
Coast, 5-8 July 2015. Opening Address.
Mattner S.W., Milinkovic M., et al., 2016. Performance of plug plants and fumigants for strawberry
runner production in Australia. In Proceedings of the International Methyl Bromide Alternative Outreach
Conference, Orlando, November 2016.
Mattner S.W., Thalavaisundaram T., et al., 2015. Virtually impermeable film improves the efficacy of
EDN Sterigas® in the Australian strawberry nursery industry. Proceedings of the International Methyl
Bromide Alternative Outreach Conference, San Diego, November 2015.
Milinkovic M., Mattner S.W, et al., 2016. Development and performance of soil-less systems for
strawberry transplant production in Australia. Abstract for the International Strawberry Symposium,
Quebec, Canada (accepted).
17
Mattner S.W., Porter I.J., et al. 2014. Critical challenges for control of soilborne pathogens in the
strawberry industry. In Proceedings of the 8th Australasian Soilborne Diseases Symposium, 10-13
November, Hobart.
Mattner S.W., Porter I.J. et al., 2014. Soil disinfestation with recaptured quarantine methyl bromide. In
Proceedings of the 8th Australasian Soilborne Diseases Symposium, 10-13 November, Hobart.
Merriman P.R., Mattner S.W., et al., 2014. National strawberry industry threatened. In Proceedings of
the 8th Australasian Soilborne Diseases Symposium, 10-13 November, Hobart.
Porter I.J., Mattner S.W., et al., 2014. Impact of methyl bromide phase out on new technologies for
control of soilborne diseases. In Proceedings of the 8th Australasian Soilborne Diseases Symposium, 10-
13 November, Hobart.
Porter, I.J., Mattner S.W. 2014. The post methyl bromide era: achievements, difficulties, and failures.
Seventh International Symposium on Chemical and Non-Chemical Soil and Substrate Disinfestation.
Torino, Italy, July 13-17 2014.
5.3 Grower Newsletter Articles:
Anon., 2014. Strawberry research ramps up. Good Fruit and Vegetables, April 2014, pg 3.
Anon., 2014. Strawberry studies. The Weekly Times, April 16, pg 72.
Anon., 2016. Registration of Tri Form 80 soil fumigant. Simply Red, Number 44, pg 10.
Fan J. & Mattner S.W. The future beyond methyl bromide – Perspectives from the US. Simply Red,
Number 43, pg 4.
Greenhalgh F.C., et al., 2016. Vic branch field day reveals critical role of plant pathology in the
strawberry industry. APPS Newsletter, 2016.
Mattner S.W., et al., 2014. Earlier yields and better establishment of strawberry runners. Strawberry
Industry Advisor Committee Annual Report 2013/14, p 4.
Mattner S.W., et al., 2014. Soil disinfestation systems for certified strawberry runners. Strawberry
Advisory Committee Annual Report 2013/14, p 10.
Mattner S.W., et al., 2015. Integrated Weed Control in the Strawberry Runner Industry with Herbicides
and Fumigants. Best Practice Flyer, VSICA, Toolangi, Victoria. (Appendix I).
Mattner S.W., et al., 2015. Q&A: What is our best alternative to methyl bromide right now? Runner
Round, September 2015, p 5.
Mattner, S.W., Milinkovic M., et al., 2015. Performance of strawberry plug plants. VicStrawberries,
Victorian Strawberry Industry Newsletter, May Edition.
Reid A., Mattner S.W., et al., 2015. Fumigation survey in Western Australia. Simply Red, Queensland
Strawberry Industry Newsletter 37, p 8, March 2015.
18
5.4 Scientific Reports:
Anon., 2013. Renomination of methyl bromide critical use for preplant soil use, structures, commodities
or objects: AUS02 CUN16 strawberry runners. Report to MBTOC.
Anon., 2014. Renomination of methyl bromide critical use for preplant soil use, structures, commodities
or objects: AUS02 CUN17 strawberry runners. Report to MBTOC.
Anon., 2015. Renomination of methyl bromide critical use for preplant soil use, structures, commodities
or objects: AUS02 CUN18 strawberry runners. Report to MBTOC.
Anon., 2015. Renomination of methyl bromide critical use for preplant soil use, structures, commodities
or objects: AUS02 CUN19 strawberry runners. Report to MBTOC.
Greenhalgh F.C., et al., 2015. Report on study tour by representatives of the Victorian strawberry
nursery industries to South Africa (6-15 Feb, 2015). VSICA report.
Horstra C., et al., 2014. Evaluation of soil-less systems for strawberry transplant production, VSICA
Report for TCSRGC.
Mattner S.W., Verheyen, G., et al., 2015. Northern Perth strawberry pathogen survey. VSICA Report.
Mattner S.W., et al., 2015. Assessment of the use of methyl bromide for soil disinfestation as a
quarantine treatment in the strawberry runner industry. VSICA report to TCSRGC.
Mattner S.W., et al., 2015. Efficacy of ethanedinitrile (EDN) for soil disinfestation in the strawberry
runner industry (2014/15). VSICA report to BOC Gases.
Mattner S.W., et al., 2015. Efficacy and plant-back of dimethyl disulphide fumigants for soil
disinfestation in the Australian strawberry nursery industry (2014/15). VSICA report to Arkema Pty Ltd.
Mattner S.W., et al. 2016. Identification of potential alternative locations to Toolangi, Victoria for runner
production. VSICA report to TCSRGC.
Mattner S.W., et al., 2016. Efficacy of Paladin® fumigants for soil disinfestation in the Australian
strawberry nursery industry. VSICA report to Arkema Pty Ltd.
Mattner S.W., et al., 2016. Fruit performance of strawberry runners produced in soil treated with
Paladin®. VSICA report to Arkema Pty Ltd.
19
6. Outcomes / Results
6.1 Development of Integrated Soil Disinfestation Systems:
6.1.1 Small-Scale Trials
Overall, no combinations were identified that controlled weeds, pathogens, and produced runner yields
to the same level as MB/Pic (500 kg/ha). Several combinations of substitute fumigants and herbicides,
however, showed promise for further evaluation.
6.1.1.1 Weed control
Weeds emerging in trials varied from site to site, but the most dominant included: Acacia spp.
Amaranthus retroflexus, Chenopodium album, Digitaria sanguinalis, Dysphania ambrosiodes,
Echinochloa crus-galli, Lolium spp., Lotus corniculatus, Persicaria maculosa, Poa annua, Raphanus
raphanistrum, Senecio vulgaris, Solanum nigrum, Sonchus oleraceus, Spergula arvensis, Stellaria media,
and Trifolium spp.
All substitute fumigants tested significantly and consistently suppressed weed emergence compared with
the untreated control, except Pic (e.g. Figure 1). The methyl isothiocyanate generators MS and Daz, or
co-application of these products with other substitute fumigants, generally controlled weeds to
equivalent levels as MB/Pic (500 kg/ha) (e.g. Figures 1 & 2). However, MS and Daz also reduced runner
yields due to crop phytotoxicity (see ‘Yield’ below). Other substitute fumigants, applied on their own
using standard techniques, did not control weeds to the same level as MB/Pic.
Figure 1. Weed emergence in soils treated with different fumigants in two field trials in the strawberry
runner industry at Toolangi, Victoria in 2014/15. Error bars represent least significant differences for
each trial, where p = 0.05.
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
Untreated
DMDS
Daz
Pic
DMDS+Daz
DMDS/Pic
Pic+Daz
DMDS/Pic+Daz
1,3-D/Pic(65:35)
1,3-D/Pic(40:60)
1,3-D/Pic(20:80)
EDNLDPE
EDNVIF
MB/Pic(500kg/ha)
WeedEm
ergence(Log
10plants/m
2 +1)
Trial1
Trial2
20
All pre-emergent herbicides tested significantly suppressed weed emergence in non-fumigated soil,
except α-pinene and chlorthal-dimethyl (e.g. Figure 2). The pre-emergent herbicides napropamide,
isoxaben, oxyfluorfen, and terbacil significantly reduced weeds in soils treated with substitute fumigants,
to levels equivalent to that in MB/Pic-treated soil. Oxyfluorfen and terbacil, however, killed or
suppressed the growth of strawberry plants (see ‘Yield’ below).
Figure 2. Weed emergence in soil treated with different combinations of fumigants and pre-emergent
herbicides in a field trial in the strawberry runner industry at Toolangi, Victoria in 2013/14. The error
bar represents the least significant difference, where p = 0.05.
The post-emergent herbicide phenmedipham significantly controlled weeds compared with the untreated
control, but fluazifop-p did not consistently do so (e.g. Figure 3). Spray programs using the pre-
emergent herbicide isoxaben and the post-emergent herbicides phenmedipham and fluazifop-p
significantly controlled weeds in untreated soils, and in soils treated with substitute fumigants (e.g. Pic
and 1,3-D/Pic (20:80)), to equivalent levels as MB/Pic (500 kg/ha) (e.g. Figures 3 & 4).
0
50
100
150
NoHerbicide
α-Pinene
Chlorthal-dimethyl
Metolachlor
Clopyralid
MS(500L/ha)
Napropamide
Isoxaben
Oxyfluorfen
Terbacil
WeedEmergence(plants/m
2) Untreated
Pic
1,3-D/Pic(20:80)
1,3-D/Pic(40:60)
MB/Pic(500kg/ha)
21
Figure 3. Weed populations in soil treated with different combinations of fumigants and pre- and post-
emergent herbicides in a trial in the strawberry runner industry at Toolangi, Victoria in 2014/15. The
herbicide combination consisted of isoxaben + phenmedipham + fluazifop-p. The error bar represents
the least significant difference, where p = 0.05.
The use of virtually impermeable barrier films, compared with LDPE, significantly increased weed control
by the substitute fumigant EDN (e.g. Figure 1), to levels equivalent to MB/Pic (500 kg/ha). The use of
VIFs did not increase weed control by 1,3-D/Pic (20:80) (data not shown). Deeper injection (to a soil
depth of 25 cm compared with 15 cm) of the substitute fumigant EDN significantly increased weed
control, but deeper application of 1,3-D/Pic (20:80) significantly decreased it (e.g. Figure 4).
Decreasing the application rate of MB/Pic from the standard of 500 kg/ha to 400 kg/ha significantly and
consistently reduced weed control (e.g. Figure 4).
22
Figure 4. Weed emergence in soil treated with combinations of fumigants, applied at different soil
depths (25 cm and 15 cm), and pre- and post-emergent herbicides in a trial in the strawberry runner
industry at Toolangi, Victoria in 2015/16. Herbicide treatment consisted of isoxaben + phenmedipham
+ fluazifop-p. The error bar represents the least significant difference, where p = 0.05.
6.1.1.2 Pathogen control
MB/Pic (500 kg/ha) was the only treatment that consistently eradicated buried inoculum of all
pathogens in soils in all trials. However, some combinations of substitute fumigants (e.g. 1,3-D/Pic
(20:80) and DMDS or DMDS/Pic + MS or Daz) showed the potential to control buried pathogens to the
same level as MB/Pic (500 kg/ha) in individual trials (e.g. Figure 5).
Natural populations of soil-borne pathogens occurred at low levels in the trials. DNA concentrations of
Pythium spp. clade F were the highest of those tested at the sites (99.2% of total pathogen DNA).
Clade F contains the species P. debaryanum, P. irregulare and P. sylvaticum, which are important
pathogens of strawberry plants. Concentrations of other strawberry pathogens at the trial sites were
extremely low: Pythium spp. clade I (0.7% of total pathogen DNA), Meloidogyne hapla (0.004% of total
pathogen DNA) and Pratylenchus penetrans and Verticillium dahliae (< 0.001% of total pathogen DNA).
DNA concentrations of Macrophomina phaseolina were not detected in soil at any of the trial sites.
At planting, most substitute fumigants significantly reduced total DNA concentrations of pathogens in
soil compared with the untreated control. However, no substitute fumigant reduced total pathogen
concentrations to the same level as MB/Pic (500 kg/ha), particularly low in the soil profile (e.g. Table 3).
There was evidence that pathogens surviving low in the profile re-colonised the upper profile in soils
treated with substitute fumigants. For example, by harvest, pathogen concentrations in soil treated with
substitute fumigants were equivalent to those in untreated soil, and significantly higher than those in the
MB/Pic (500 kg/ha) treatment (e.g. Table 3).
0
10
20
30
40
50
60
70
80
Untreated
EDN,25cm
EDN,15cm
1,3-D/Pic(20:80),25cm
1,3-D/Pic(20:80),15cm
MB/Pic(400kg/ha)
MB/Pic(500kg/ha)
WeedEmergence(plants/m
2)
NoHerbicide
Herbicides
23
Figure 5. Viability of buried inoculum (infected barley seed) of Fusarium oxysporum in soils treated
with different fumigants in trials in the strawberry runner industry at Toolangi, Victoria in 2015/16. The
error bar represents the least significant difference, where p = 0.05.
Table 3. Total DNA concentrations of pathogens (Pythium clades I & F, Meloidogyne hapla,
Pratylenchus penetrans, and Verticillium dahliae) in soil at different depths following treatment with
fumigants in a field trial in the strawberry runner industry at Toolangi, Victoria in 2014/15. Values
followed by different letters in each sampling period (planting or harvest) are significantly different,
where p ≤ 0.05.
0
0.2
0.4
0.6
0.8
1
1.2
1.4
Untreated
DMDS
MS(500L/ha)
EDN
Daz
Pic
DMDS/Pic
DMDS+MS
DMDS+Daz
DMDS/Pic+M
S
DMDS/Pic+Daz
1,3-D/Pic(20:80)
MB/Pic(500kg/ha)
ArcSine
Inoculum
Viability
24
The use of VIF barriers, compared with LDPE, did not significantly increase pathogen control by the
substitute fumigants EDN and 1,3-D/Pic (20:80) (e.g. Table 3). Deeper injection (to a soil depth of
25 cm compared with 15 cm) of the substitute fumigants EDN and 1,3-D/Pic (20:80) did not significantly
increase pathogen control at soil depths of 40-50 cm (e.g. Figure 6). The use of specific fungicides
active against Pythium spp. (fosetyl-Al and thiophanate methyl / etridiazole) did not increase pathogen
control in soils treated with substitute fumigants (data not shown).
Decreasing the application rate of MB/Pic from the standard of 500 kg/ha to 400 kg/ha significantly
reduced pathogen control (e.g. Figure 6).
Figure 6. Total DNA concentrations of pathogens (Pythium clades I & F, Meloidogyne hapla,
Pratylenchus penetrans, and Verticillium dahliae) in soil at different soil depths (0-10 cm and 40-50 cm)
following treatment with fumigants injected to different soil depths (25 cm and 15 cm) in a field trial in
the strawberry runner industry at Toolangi, Victoria in 2015/16. The error bar represents the least
significant difference where p = 0.05.
6.1.1.3 Runner yields
Soil disinfestation with several substitute fumigants showed potential for producing runner yields
equivalent to MB/Pic, including DMDS/Pic co-applied with herbicides, 1,3-D/Pic (20:80) co-applied with
herbicides, and EDN sealed under VIF (e.g. Figures 7, 8, 9 & 10). Several substitute fumigants caused
crop phytotoxicity and significantly reduced runner yields, particularly the methyl isothiocyanate
generators Daz and MS (e.g. Figures 7 & 8). Formulations of 1,3-D/Pic containing high concentrations
of 1,3-D (i.e. 1,3-D/Pic (65:35) and 1,3-D/Pic (40:60)) also caused phytotoxicity in runner crops, and
produced significantly lower runner yields than formulations containing low concentrations of 1,3-D (i.e.
1,3-D/Pic (20:80)) (e.g. Figure 7).
25
Figure 7. Runner yields in soils treated with different fumigants in two field trials in the strawberry
runner industry at Toolangi, Victoria in 2014/15. Trial 1 was with the cultivar Gaviota, and Trial 2 was
with the cultivar San Andreas. Error bars represent least significant differences for each trial,
where p = 0.05.
The pre-emergent herbicides oxyfluorfen and terbacil killed or severely stunted the growth of strawberry
runners (e.g. Figure 8). Application of isoxaben at planting significantly increased runner yields in
untreated soil, and in soil treated with substitute fumigants (e.g. Figures 8 & 9). Runner yields in plots
treated with isoxaben and substitute fumigants were equivalent to those in MB/Pic-treated soil.
The post-emergent herbicides phenmedipham and fluazifop-p did not cause phytotoxicity or losses in
yield of strawberry runners. In untreated soils, post-emergent application of phenmedipham and
fluazifop-p significantly increased runner yields. Plots treated with 1,3-D/Pic (20:80) followed by spray
programs of the pre-emergent herbicide isoxaben and the post-emergent herbicides phenmedipham and
fluazifop-p produced equivalent runner yields to MB/Pic (500 kg/ha).
The use of VIF barriers with the substitute fumigant EDN significantly increased runner yields, compared
with the use of LDPE (e.g. Figure 7). Deeper injection (25 cm depth compared with 15 cm) of EDN
under VIF also significantly increased runner yields (e.g. Figure 10). Depth of application of the
substitute fumigant 1,3-D/Pic (20:80) did not affect runner yields (e.g. Figure 10).
Decreasing the application rate of MB/Pic from the standard of 500 kg/ha to 400 kg/ha significantly
reduced runner yields (e.g. Figure 10).
0
20
40
60
80
100
120
Untreated
DMDS
Daz
Pic
DMDS+Daz
DMDS/Pic
Pic+Daz
DMDS/Pic+Daz
1,3-D/Pic(65:35)
1,3-D/Pic(40:60)
1,3-D/Pic(20:80)
EDNLDPE
EDNVIF
MB/Pic(500kg/ha)
RunnerYield(plants/m
)
Trial1
Trial2
26
Figure 8. Runner yields (cv. Monterey) in soil treated with different combinations of fumigants and
pre-emergent herbicides in a field trial in the strawberry runner industry at Toolangi, Victoria in 2013/14.
The error bar represents the least significant difference, where p = 0.05.
Figure 9. Runner yields (cv. San Andreas) in soil treated with different combinations of fumigants and
pre- and post-emergent herbicides in a trial in the strawberry runner industry at Toolangi, Victoria in
2014/15. The herbicide combination consisted of isoxaben + phenmedipham + fluazifop-p. The error
bar represents the least significant difference, where p = 0.05.
0
20
40
60
NoHerbicide
α-Pinene
Chlorthal-dimethyl
Metolachlor
Clopyralid
MS(500L/ha)
Napropamide
Isoxaben
Oxyfluorfen
Terbacil
Run
nerYield(plants/m) Untreated
Pic
1,3-D/Pic(20:80)
1,3-D/Pic(40:60)
MB/Pic(500kg/ha)
0
20
40
60
80
100
120
NoHerbidicide
AITC
MS(500L/ha)
Phenmedipham
Fluazifop-p
Isoxaben
Napropamide
HerbicideCombina
on
Run
nerYield(plants/m) Untreated
Pic
1,3-D/Pic(20:80)
MB/Pic(500kg/ha)
27
Figure 10. Runner yields (cv. Albion) in soil treated with combinations of fumigants, applied at different
soil depths (25 cm and 15 cm), and pre- and post-emergent herbicides in a trial in the strawberry runner
industry at Toolangi, Victoria in 2015/16. Herbicide treatment consisted of isoxaben + phenmedipham
+ fluazifop-p. The error bar represents the least significant difference,
where p = 0.05.
6.1.1.4 Plant-back:
Concentrations of the active generated by Daz (methyl isothiocyanate) persisted in soil for 126 days
after application (Figure 11). Concentrations of 1,3-D persisted in soil for 84 days after treatment with
1,3-D/Pic (65:35) or (40:60), but only 42 days after treatment with 1,3-D/Pic (Figure 12). In
comparison, concentrations of MB persisted in soil for 14 days after treatment with MB/Pic 500 kg/ha
(Figure 11 & 12).
Models predicted that the plant-back times for the substitute fumigants Pic and 1,3-D/Pic (20:80) were
similar to MB/Pic 500 kg/ha (Table 4). Formulations of 1,3-D/Pic containing high concentrations of
1,3-D (i.e. 65:35 and 40:60) required longer plant back times than formulations containing low
concentrations of 1,3-D (i.e. 20:80).
0
10
20
30
40
50
60
70
80
Untreated
EDN,25cm
EDN,15cm
1,3-D/Pic(20:80),25cm,LDPE
1,3-D/Pic(20:80),15cm,LDPE
MB/Pic(400kg/ha)
MB/Pic(500kg/ha)
RunnerYield(plants/m
)
NoHerbicide
Herbicides
28
Figure 11. Concentrations of methyl isothiocyanate (residual active in Daz + Pic) and MB (active in
MB/Pic) following treatment in a field trial in the strawberry runner industry at Toolangi, Victoria in
2014/15.
Figure 13. Concentrations of 1,3-D (residual active in 1,3-D/Pic formulations) and MB (active in
MB/Pic) following treatment in a field trial in the strawberry runner industry at Toolangi, Victoria in
2014/15.
0.00
0.50
1.00
1.50
2.00
2.50
3.00
0 20 40 60 80 100 120 140
Concentra
onofAcve(Log 1
0ppm+1)
TimeA erTreatment(days)
Daz+Pic
MB/Pic(500kg/ha)
0.00
0.50
1.00
1.50
2.00
2.50
3.00
0 20 40 60 80 100
Concentra
onofAcve(Log 1
0ppm+1)
TimeA erFumiga on(days)
1,3-D/Pic(65:35)
1,3-D/Pic(40:60)
1,3-D/Pic(20:80)
MB/Pic(500kg/ha)
29
Table 4. Predicted optimum plant-back times for different fumigants in a field trial in the strawberry
runner industry at Toolangi, Victoria in 2014/15, using a modelling approach (Mattner et al., 2003).
6.1.2 Commercial Trials
6.1.2.1 Commercial trials with Pic
Pathogen concentrations in soil at planting and weed emergence were significantly higher in two runner
fields treated with Pic, compared with MB/Pic (500 kg/ha). In one trial, runner yields in a field treated
with Pic were equivalent to those in a field treated with MB/Pic (500 kg/ha). In the other trial, runner
yields were significantly lower in soils treated with Pic than in those treated with MB/Pic (500 kg/ha).
Subsequent fruit yields at Millgrove, Victoria from runners produced in Pic-treated soils in the nursery
were significantly lower than those from runners produced in MB/Pic-treated soils in the nursery (9%
lower). This was equivalent to a 10% loss in revenue from fruit, or $0.45 less per plant. At the final
fruit harvest, the incidence of Pythium rot was significantly higher in plants grown from runners
produced in Pic-treated soil (50% of structural roots with lesions) than in those from runners produced
in MB/Pic-treated soil (33% of structural roots with lesions). The incidence of recovery of Pythium spp.
from the structural roots of strawberry plants grown from runners produced in soil treated with Pic was
significantly higher (38%) than those grown from runners produced in MB/Pic-treated soil (12%).
30
Table 5. Summary of results from five commercial trials comparing the efficacy of substitute fumigants
to MB/Pic in the strawberry runner industry at Toolangi, Victoria. Means are followed by 95%
confidence intervals.
Figure 14. Cumulative fruit yields (cv. Albion) in a field trial at Millgrove, Victoria from runners sourced
from different fumigant treatments in the strawberry nursery industry. The error bar represents the
least significant difference, where p = 0.05, at the final harvest.
31
6.1.2.2 Commercial trials with 1,3-D/Pic (20:80) + isoxaben:
At planting, pathogen concentrations in soil were significantly higher in three fields treated with
1,3-D/Pic (20:80) + isoxaben, compared with MB/Pic (500 kg/ha) (Table 5). In two of the three trials,
weed control and runners yields were equivalent in fields treated with 1,3-D/Pic (20:80) + isoxaben, or
MB/Pic. In the other trial, weed control and runner yields were significantly lower in fields treated with
1,3-D/Pic (20:80) + isoxaben than in those treated with MB/Pic (500 kg/ha).
Subsequent fruit yields at Wanneroo, Western Australia from runners produced in 1,3-D/Pic (20:80) +
isoxaben-treated soils in the nursery were significantly lower than those from runners produced in
MB/Pic-treated soils in the nursery (15% lower fruit yields), particularly late in the season when
wholesale prices for fruit were high (Figure 15). This was equivalent to a loss in revenue from fruit of
16%, or $1.17 per plant. There was no significant difference in the incidence of Fusarium wilt or
Fusarium oxysporum recovered from the roots of strawberry plants grown from runners produced in
1,3-D/Pic (20:80) + isoxaben or MB/Pic treatments (data not shown).
Figure 15. Cumulative fruit yields (cv. Fortuna) in a field trial at Wanneroo, Western Australia from
runners sourced from different fumigant treatments in the strawberry nursery industry. The error bar
represents the least significant difference, where p = 0.05, at the final harvest.
0
200
400
600
800
1000
1200
May
June
July
August
September
October
November
MarketableFruitYield(g/plant)
MB/Pic(500kg/ha)
Untreated
1,3-D/Pic(20:80)+isoxaben
32
6.2 Soil-less Systems for Production of Strawberry Runners:
6.2.1 Feasibility Analyses
A literature review on soil-less systems for strawberry runner production was published in the scientific
literature (Mattner et al., 2016; see ‘Scientific Refereed Publications’), in a report submitted to industry,
the Department of the Environment and United Nations, and presented as an opening address at the
International Convention on Soil-less Culture (see ‘Outputs’). The key recommendation from the review
was that further research is needed to improve the economics and consistency of fruit yields from
transplants produced in soil-less systems. In particular, the combination of micro-propagated mother
plants, tip production in hydroponics, and conditioned plug transplants shows the greatest potential.
Results from a partial budget analysis were also published in the scientific literature (Mattner et al.,
2014; see ‘Scientific Refereed Publications’) and in critical-use nominations submitted to the United
Nations. Analysis showed that production of Mother (third generation) and Certified (fourth generation)
runners in substrate bins would result in net revenue losses of nearly $800,000/ha, or 83% (Table 6).
Prices of runners would need to increase from $0.34 in MB/Pic-treated soils, to $2.00 per transplant in
substrate bins just to break even (Table 6).
Table 6. Summary of the economic impacts of soil-less systems (substrate bins) for production of the
Certified generation of strawberry runners at Toolangi, Victoria.
33
6.2.2 Study Tours
6.2.2.1 Japan
In the Nagasaki Prefecture of Japan, strawberry fruit growers produce their own transplants (70-80%)
using soil-less rack systems. In this system, mother plants are grown in soil-less substrates (65%
mountain soil: 15% peat moss: 10% coconut coir: 10% composted pine bark) in pots. Daughter plants
are pinned into smaller pots containing the soil-less substrate, and these form the planting stock for the
subsequent generation. Pathogen-tested stock are also produced using the same method by dedicated
nurseries, but only occupy 4% of the market due to their high cost (A$2.40 per plant). Key production
and economic differences (Table 7) mean that the Japanese rack system is not a direct substitute for
runner production in MB/Pic-treated soil in Australia. However, the Victorian Runner Certification
Scheme has adopted a similar substrate system to Japan for production of Nucleus stock (first
generation) runners.
Table 7. A comparison of key production, biosecurity, and economic differences that prevent Japanese
rack systems from being an immediate substitute for Mother and Certified stock production in Victoria,
Australia.
34
6.2.2.2 Europe
In 2014, a contingent of Victorian runner growers and VSICA members visited strawberry nurseries in
Spain (Ekland Group, Viveros Campiñas, and Viveros Mozoncillo) and the Netherlands (NAK, Goosens
Flevo Plant, De Kemp BV, Neesen BV, and Van Alphen). Spanish nurseries reported that they import
nucleus runners from California, USA, which are produced in soil treated with MB/Pic under a quarantine
exemption. The Dutch strawberry nursery industry reported that it produced 1 billion transplants p.a. It
was also reported that up to 30% of these transplants are containerised tray plants produced in soil-less
media. Ninety percent of the runner tips used to produce tray plants are grown in the field in soil.
Therefore, this system does not eliminate the need for soil disinfestation and does not present the
Victorian runner industry with a substitute to MB/Pic. The remaining 10% of runner tips used to
produce tray plants in the Netherlands were produced in hydroponic systems. This system does
eliminate the need for soil disinfestation, but only occupies a small proportion of transplant production
by the European industry (3% in total, equivalent to 3 million transplants). Economic, market, and
environmental differences mean that European hydroponic / tray plant systems are not an immediate
substitute for MB/Pic and runner production in Australia (Table 8).
Table 8. A comparison of key production, biosecurity, and economic differences that prevent European
tray plant systems from being an immediate substitute for Mother and Certified stock production in
Victoria, Australia.
35
6.2.2.3 South Africa
Nursery growers at Brits, Ceres, and George produced plug plants in similar hydroponic systems to those
observed in Europe, but designs (e.g. support structures, gutters, netting, substrate) varied considerably
from farm to farm. The price of plug plants was only 1.4 times more than bare-rooted runners
produced in fumigated soil, due to the relatively low costs of labour (A$1.50/hour) and infrastructure.
None of the technologies used for the production of tips and plug plants in soil-less systems in South
Africa, however, are immediately transferable for the economic production of plug plants in Australia
(Table 9). However, design aspects from hydroponics systems in Europe and South Africa were used to
develop a prototype hydroponic system for evaluation of plug plant production in Victoria (see below).
Table 9. A comparison of key production, biosecurity, and economic differences that prevent South
African plug plant systems from being an immediate substitute for Mother and Certified stock production
in Victoria, Australia.
36
6.2.3 Research on Soil-less Systems
6.2.3.1 Transplant production
Hydroponic production in a screenhouse produced significantly more transplants (up to 88% more) than
the same system outdoors (e.g. Figure 16). Under screenhouse conditions, yields of transplants of most
cultivars tested were significantly higher (by up to 90%) in the hydroponic systems than those in large
bins containing substrate. Yields were also significantly higher (by up to 96%) for most cultivars in the
hydroponic system in the screenhouse compared with field production in soils treated with MB/Pic.
Figure 16. Transplant yields (transplants/m2) of strawberry cultivars in soil-less systems and in field soil
treated with MB/Pic (500 kg/ha) at Toolangi, Victoria in 2014/15. Bars represent 95% confidence
intervals.
6.2.3.2 Yields of plug plants in the runner industry
In most fumigant treatments, runner yields from plug plants were significantly higher than those from
bare-rooted runners (Figure 17). In soils treated with MB/Pic, however, plug plants and bare-rooted
runners produced equivalent runner yields. Plug plants grown in soils treated with 1,3-D/Pic (20:80)
produced equivalent runner yields to bare-rooted mother plants grown in soils treated with MB/Pic
(Figure 17).
0
50
100
150
200
250
300
350
400
SanAndreas Albion Monterey Fes val Camarosa
Yield(tran
splants/m
2 )
OutdoorHydroponics
ProtectedHydroponics
SubstrateBins
FumigatedSoil
37
6.2.3.3 Yields of plug plants in the fruit industry
Fruit yields from plug plants produced in the hydroponic system in the screenhouse were highly variable
across Australia. At Wanneroo, Western Australia, plug plants produced significantly less fruit (up to
40% less) than bare-rooted runners (Figure 18). This was equivalent to a loss in revenue from fruit of
42%, or $2.68 less per plant. At Millgrove Victoria, however, plug plants produced significantly more
fruit than bare-rooted runners (22% more) (Figure 19). This was equivalent to an increase in revenue
from fruit of 23%, or $1.10 more per plant.
Figure 17. Commercial yields (runners / m of row) from plug plant and bare-rooted mothers of
strawberry (cv. San Andreas) grown in soil treated with different fumigant treatments at Toolangi,
Victoria in 2014/15. The bar represents the least significant difference where p = 0.05.
0
20
40
60
80
100
120
MB/Pic(50:50)500kg/ha
1,3-D/Pic(20:80)400kg/ha
Pic350kg/ha Untreated
Yield(run
ners/m
ofrow
)
PlugPlant
Bare-RootedRunner
LSD(p=0.05)
38
Figure 18. Total fruit yields of different cultivars of strawberry grown from bare-rooted runners or plug
plants in a field trial at Wanneroo, Western Australia in 2015. The bars represent the least significant
difference where p = 0.05.
Figure 19. Cumulative fruit yields of strawberry (cv. Albion) grown from bare-rooted runners or plug
plants in a field trial at Millgrove, Victoria in 2014/15. The bar represents the least significant difference
where p = 0.05.
0
200
400
600
800
1000
1200
Fortuna Benicia SanAndreas Albion
MarketableFruitYield(g/plant)
Bare-Root
Plug
39
7. Evaluation and Discussion
7.1 Discussion:
7.1.1 Integrated Soil Disinfestation Systems
Of the 102 different combinations of substitute fumigants, herbicides and fungicides investigated in this
project, none controlled pathogens, weeds and produced runner yields to the same level as MB/Pic.
Despite this, research made considerable progress towards the development of integrated soil
disinfestation systems as substitutes to MB/Pic. At the beginning of this project, crop phytotoxicity and
poor weed control were two of the important issues preventing the successful adoption of substitute
fumigants and forcing the strawberry runner industry to apply for critical-use exemptions for MB. This
project developed potential strategies for runner growers to manage these issues. For example,
research demonstrated that 1,3-D/Pic formulations containing low concentrations of 1,3-D (i.e. 1,3-D/Pic
(20:80)) had short residence and plant-back times in soils at Toolangi, and therefore reduced the risk of
crop phytotoxicity. Furthermore, research identified that co-application of specific pre- and post-
emergent herbicides (isoxaben, phenmedipham and fluazifop-p) with 1,3-D/Pic (20:80) managed weeds
to similar levels as MB/Pic, without reducing runner yields. Other substitute fumigants (e.g. EDN and
DMDS/Pic) applied with these herbicides also showed the capacity to control weeds and produce runner
yields equivalent to MB/Pic. However, none of these substitute fumigants (except 1,3-D/Pic (20:80))
and herbicides (except fluazifop-p) is currently registered or available for use by the runner industry.
The most significant problem with substitute fumigants was their failure to control soil-borne pathogens
as well as MB/Pic. A high level of control of pathogens in strawberry nurseries is essential to maintain
phytosanitary standards and support market access of runners from region to region. Of the substitute
fumigants investigated, research showed that 1,3-D/Pic (20:80) provided the best control of soil-borne
pathogens. This fumigant did not, however, adequately control soil-borne pathogens deep in the soil
profile. By the time of runner harvest, pathogens had recolonised the upper profile in soils treated with
1,3-D/Pic (20:80), and populations were no different to those in untreated soils (and significantly higher
than soils treated with MB/Pic). Deeper injection and application under virtually impermeable barrier
film did not improve pathogen control with 1,3-D/Pic (20:80). In contrast, deeper injection under
virtually impermeable film did improve pathogen control by the substitute fumigant EDN, but not to the
same level as MB/Pic.
Co-application of the methyl isothiocyanate generators, Daz and MS, showed the capacity to improve
pathogen control with the substitute fumigants 1,3-D/Pic (20:80) and DMDS/Pic. However, these
combinations also killed or severely stunted strawberry plants. Residues of methyl isothiocyanate
persisted in soils at Toolangi for 126 days and required long plant-back times of over 3 months, even
when treated in warmer temperatures in Spring. This means that Daz and MS would be particularly
difficult for growers to implement in their rotation systems in the Victorian runner industry, unless they
are applied well before other fumigant treatments.
A potential consequence of poor pathogen control with substitute fumigants in the runner industry is
lower yields in the fruit industry. In trials in the fruit industry in contrasting locations around Australia,
runners produced in soils treated with substitute fumigant systems in the nursery industry produced less
fruit than those produced in soils treated with MB/Pic in the nursery (9 – 15% less, equivalent to 10 –
16% less revenue from fruit). In one trial in the fruit industry, strawberry plants from runners produced
40
in soils treated with substitute fumigants had higher incidence of black root rot and recovery of Pythium
pathogens than plants from runners produced in MB/Pic-treated soils. Furthermore, these higher
disease levels were associated with lower yields of fruit. These results generally concur with previous
estimates that the loss of MB/Pic without a suitable substitute would result in yield losses in the fruit
industry of up to 15%, worth $30-60 M p.a. (BS01004). This demonstrates that the impact of the loss
of MB from the runner industry, without an effective substitute, is likely to be greater on the fruit
industry than on the nurseries.
Further research urgently needs to be conducted on methods to improve control of pathogens using
substitute fumigant / herbicide systems in the runner industry, including:
1. Deeper application (up to 30 cm) of substitute fumigants to control pathogens deeper in the soil
profile.
2. Formulation or co-application of some substitute fumigants (e.g. EDN and DMDS) with higher
concentrations of Pic. This is because Pic is highly active against fungal pathogens
(Desmachelier and Vu, 1998).
3. Further evaluation of totally impermeable films, to increase exposure times of pathogens to
substitute fumigants.
4. Application of methyl isothiocyanate generating fumigants well before (6 months) co-application
with other substitute fumigants.
5. Higher dosage rates of key substitute fumigants in experimental settings.
6. Integration of biofumigant cropping practices with the use of substitute fumigants.
7. Different combinations of fungicides co-applied with substitute fumigants.
8. Development of bystander safety and environmental emission data to further support the
registration of some substitute fumigants.
9. Evaluation of new substitute fumigants (e.g. propylene oxide and propylene oxide / Pic).
10. Commercial trials investigating runner production in different locations around Australia that
may have soil-types more suited to the use of substitute fumigants.
The Victorian runner industry may need to consider further applications for critical-use exemptions for
MB while this research occurs.
7.1.2 Soil-less Systems
Soil-less methods of production have so far proven too costly, compared with bare-rooted runner
production in the field, for full adoption by the Australian strawberry nursery industry (Menzel et al.,
2010; Mattner et al., 2014; Mattner et al., 2016a). For example, partial budget analysis showed that
operating profit margins for production of bare-rooted Mother (third generation) and Certified (fourth
generation) runners would decrease from 8% in MB/Pic-treated soil to -83% in soil-less substrates, and
therefore is not economically viable. The increased cost of bare-rooted runners produced in soil-less
substrates is mostly due to high infrastructure and labour costs. However, soil-less technologies are
viable for use in the early generations of runner multiplication, where plants have their highest value.
Results from this project showed that protected hydroponic systems for the production of plug plants
were highly efficient, in terms of transplant yields per unit area, for early generations of strawberry
runners. Despite being cheaper, outdoor hydroponics systems were less efficient for production of
transplants and exposed plants to the risk of infection by pathogens such as viruses and phytoplasmas
transmitted by insects. For these reasons, protected systems are currently considered the most suitable
for production of the early generations of runners. The Victorian runner industry has adopted soil-less
41
systems for the production of the first two generations (Nucleus and Foundation stock) in the
multiplication scheme.
Prior to this project, the performance of plug plants for runner production had not been evaluated in
Australia. Results showed that plug plants produced higher yields of runners than bare-rooted mother
plants, when grown in soils treated with substitute fumigants to MB/Pic. This was most likely due to the
earlier stolon growth of plug plants compared with bare-rooted runners, which provided cover and
competed better with the high populations of weeds in soils treated with substitute fumigants. Plug
plants grown in soils treated with the substitute fumigant 1,3-D/Pic (20:80) produced equivalent yields
of runners to bare-rooted mother plants grown in soils treated with MB/Pic. However, further research
is needed on methods and integrated treatments to improve control of soil-borne pathogens with
1,3-D/Pic (20:80) (see above). Nonetheless, the use of plug plants combined with substitute fumigants
to MB/Pic, and other integrated treatments, warrants further investigation as a substitute system to
MB/Pic for runner production.
Previous research in Australia has evaluated the suitability of plug plants for strawberry fruit production.
Studies generally showed that plug plants did not produce higher or earlier fruit yields than bare-rooted
runners (Menzel and Waite, 2006; Menzel et al., 2010; Mattner et al., 2016a). In the current project,
research showed that yields of fruit from plug plants were highly variable compared with bare-rooted
runners produced in MB/Pic-treated soil (ranging from producing 23% more fruit to 40% less fruit).
Plug plants would need to produce consistently higher and/or earlier yields to justify their increased cost
and adoption by the fruit industry. Further research is needed on the physiology of plug plants and their
possible conditioning to achieve more consistent and higher fruit yields, before they could be considered
a technically and economically feasible option to production of bare-rooted runners in MB/Pic-treated
soils.
7.2 Impact, Consequences, and Evaluation:
At the beginning of this project, the anticipated outcomes from the research program were:
(1) Industry has an internationally recognised R&D program that allows continued nominations for MB
under critical-use exemptions in the runner industry, and prevents reductions in profits for the fruit
industry, while viable alternatives are being developed.
Achieved.
Immediately following approval of this project, the Victorian runner industry was in full compliance with
Decision IX/6 under the Montreal Protocol because an approved R&D program to identify substitutes to
MB was in place. This led to critical-use exemptions for the use of MB in the Victorian runner industry
being fully re-instated in 2015, while research progressed on technically and economically feasible
substitutes. It also allowed the runner industry to apply for four further nominations for critical-use
exemptions for MB in 2016 (approved), 2017 (approved), 2018 (approved), and 2019 (under
consideration) because research in this project showed that the runner industry does not currently have
technically or economically feasible substitutes available. This has prevented yield and revenue losses in
the fruit industry initially estimated at up to 15% and $60 M p.a. (see above), while research on
identifying viable substitutes for the runner industry continued.
42
(2) Federal and state government make considered assessment of the quarantine status of MB use in
the runner industry. This provides time for the development of suitable substitutes to MB if approval is
granted.
Partially Achieved.
In meetings organised and facilitated through this project, federal and state government have
considered whether the current use of MB in the strawberry runner industry qualifies as a quarantine
application, which is exempt from phase-out. As a result, federal government (Department of
Agriculture and Water Resources) provided the runner industry with a framework to apply for a
quarantine exemption for MB. A draft application was prepared based on this protocol, and submitted
to the runner industry for consideration. Currently, federal and state government agencies in Australia
do not consider the use of MB in the runner industry a quarantine application, as is the case in the USA.
(3) MB is phased out in the strawberry runner industry if soil disinfestation or soil-less production
systems are developed that are technically feasible, effective, economically viable, and meet current
certification standards.
Partially achieved.
Research and analysis in this project showed that there are currently no technically or economically
feasible substitutes to MB/Pic available to the runner industry. This research allowed the industry to
apply for critical-use exemptions for MB from the UN, while research continued on identifying more
suitable substitutes. This has saved the fruit industry from anticipated losses of up to $60 M p.a. (see
above).
Despite the lack of immediate substitutes, research made considerable progress towards the
development of substitute systems to replace MB/Pic. For example, it identified more efficient soil-less
systems for production of plug plants (hydroponics). These systems are now partially adopted by the
Victorian runner industry for production of the Foundation stock (second generation runners) and, with
further evaluation and development, may be suited to Mother stock (third generation runners)
production.
At the beginning of this project, crop phytotoxicity and poor weed control were two important issues
preventing the successful adoption of substitute fumigants by the Victorian runner industry. Research
developed potential strategies for runner growers to manage these issues, including the use of 1,3-D/Pic
formulations containing low concentrations of 1,3-D (i.e. 1,3-D/Pic (20:80)), and the integrated use of
specific pre- and post-emergent herbicides with key substitute fumigants. The remaining issue is less
effective control of soil-borne pathogens with substitute fumigants compared with MB/Pic. This project
developed a 10-point research plan aimed at resolving the issue of poor pathogen control with
substitute fumigant systems (see Discussion above). Based on this research plan, current research
progress, and the anticipated registration of key substitute fumigants, industry has developed a
transition plan to phase-out MB, and presented this to plan the federal government agencies and the
United Nations.
43
Other outcomes resulting or supported by this project include:
1. All Victorian runner growers have commenced commercial-scale trialling and practising
production with substitute fumigants and herbicides in preparation for their eventual
registration and use. Runners from these blocks will not be Certified and sold.
2. Data from this project supported the successful registration of 1,3-D/Pic (20:80) (TriForm80®)
in Australia in 2016, not only for runner growers, but also for strawberry fruit and other
horticultural industries.
3. Chemical companies are using data from this project to support registration applications for
other key substitute fumigants (including EDN and DMDS).
4. New fumigants (DMDS and DMDS/Pic) were imported into Australia for trial and registration
purposes.
5. New barrier films (VIFs and TIFs) for soil fumigation are imported and available commercially
through fumigant contractors. For the first time in Australia, local plastics manufacturers have
imported equipment and commenced manufacture of TIF for use in Australian horticulture.
6. Spading rigs for improved application of MS are imported and available commercially to
horticultural growers through fumigant contractors.
7. Hydroponic systems for production of plug plants are adopted for the production of Foundation
stock (second generation runners), and the runner industry is currently constructing prototype
systems for evaluation of hydroponics for later generations of runners.
8. The runner industry is commercially producing plug plants from tips produced in MB/Pic-treated
soils, for widespread evaluation trials across the strawberry fruit industry.
Together, these outcomes demonstrate uptake and use of information and outputs from this project by
industry, chemical companies, plastics manufacturers, fumigant contractors, and government.
Apart from achieving significant outcomes for industry (see above), the effectiveness and quality of the
research in this project can also be measured by:
1. The production of five refereed publications (see ‘Scientific Refereed Publications’), and the
prospect of developing further journal papers after the completion of the project.
2. Invitations from the conveners of the International Convention and Exhibition on Soil-less
Culture and Asia-Pacific Seed Congress to present research from the project as opening and
keynote addresses.
3. A request from the Victorian Branch of the Australasian Plant Pathology Society to tour the
nursery industry and research sites within this project.
In addition to research, this project also conducted a communication program that delivered an average
of more than one activity or output per month to strawberry growers (see ‘Outputs’). Key components
of the communication program that proved particularly successful included: 1. Conducting research trials, field days and meetings on growers’ properties. This allowed
growers to review the results and outcomes of research through oral presentations, assess the
performance of treatments in the field, and to provide direct feedback on research directions
and treatments. An example of grower input into the research was the concept of calculating
the revenue through the season from different treatments in evaluation trials in the fruit
industry.
2. Conducting study tours for runner growers of overseas nursery industries (Japan, Europe,
South Africa) that have already transitioned or partially transitioned away from the use of
MB/Pic. Growers provided rapid evaluation of methods used overseas for their practicality and
44
suitability for adoption into the Victorian runner industry. For example, specific features of
hydroponics systems used overseas were immediately captured and incorporated into prototype
designs evaluated in this project. This approach fast-tracked and maximised the efficiency of
the hydroponic systems constructed in this project, and allowed their evaluation using world’s
best practices.
Work in this project contributed to the project team being presented the 2016 Industry Award from the
Victorian Strawberry Growers Association for recognition and appreciation of efforts to the strawberry
industry.
45
8. Recommendations
8.1 Recommendations to the Strawberry Runner Industry:
1. Currently substitute fumigants and integrated soil disinfestation systems do not control soil-
borne pathogens as well as MB/Pic. Industry needs to continue to support ongoing research
aimed at improving pathogen control with substitute soil disinfestation systems. Industry should
consider continued applications for critical-use exemptions for MB following the transition plan
developed through this project, while further research is undertaken and key substitute
fumigants are undergoing registration in Australia. If successful, this move would safeguard the
strawberry fruit industry from expected losses in yield (15%) and income ($60 M p.a.), while
substitute systems to MB for the runner industry are in development.
2. If ongoing research fails to identify methods to improve control of soil-borne pathogens with
substitute fumigants to MB/Pic, the runner industry should consider submitting an application to
federal and state governments requesting a re-classification of the use of MB/Pic for soil
disinfestation in the runner industry to a quarantine application. This would exempt MB from
phase-out, and allow additional time for further research to develop more suitable substitutes
for MB/Pic.
3. Industry needs to further consider the possibility of moving to other areas in Australia that may
have soil types and environments that are better suited to the use of substitute fumigants. This
would require industry to undertake commercial runner trials with substitute fumigants in
different regions of Australia with lighter soil types than those at Toolangi, Victoria. It would
also involve evaluation trials in the fruit industry to prove that runners grown at these alternate
locations produce the same fruit yields as those grown in soils treated with MB/Pic at Toolangi.
Finally, it would require a detailed analysis of the economic, social, and environmental costs of
potentially moving the runner industry from Toolangi to an alternate location.
4. If the above recommendations fail, the runner industry needs to further consider potential
litigation risks, and the viability of the industry in Australia in the medium to longer term.
8.2 Recommendations to the Victorian Strawberry Industry Certification
Authority (VSICA):
5. Soil disinfestation with MB/Pic has been very successful in enabling runner crops in Victoria to
meet the certification standards for the incidence of symptoms of soil-borne diseases. However,
VSICA needs to consider how it will certify runners following the phase-out of MB. Research in
this and previous projects has quantified DNA concentrations of key pathogens in soil at
Toolangi, Victoria following treatment with MB/Pic. One option for runner certification in the
future is to develop soil-sampling strategies and set thresholds for key pathogens based on
concentrations measured in MB/Pic-treated soils (e.g. 0 pg DNA/g soil for Macrophomina
phaseolina at planting).
46
8.3 Recommendations to the Strawberry Fruit Industry:
6. The loss of MB/Pic from strawberry nurseries, without a suitable substitute, will have a greater
impact on the strawberry fruit industry than on the runner industry. This project showed that
the use of the best substitute fumigants currently available to the runner industry would result
in yield losses of fruit of between 9 - 15%, and revenue losses from fruit of 10 – 16%
(equivalent to up to $60 M p.a). Evidence showed that these losses in the fruit yield were
associated with higher levels of soil-borne pathogens in runners. The strawberry fruit industry
needs to consider whether a greater proportion of its levy funds should be directed towards
improving control of soil-borne pathogens using substitutes to MB/Pic in the runner industry, in
order to maintain current productivity and profit levels in the fruit industry.
8.4 Recommendations to Government:
7. The use of MB to treat strawberry fruit imported from overseas is approved in Australia, under a
quarantine exemption, to prevent biosecurity threats from pathogens and pests entering this
country. Some of the countries that Australia currently imports strawberry fruit from still have
access to MB for soil disinfestation in their runner industries, under a quarantine exemption (e.g.
USA). However, MB is not currently approved for use in the Australian runner industry under a
quarantine exemption, even though it is now primarily used to prevent the spread of soil-borne
pathogens from state to state. The Australian strawberry fruit industry is worth $450 M p.a. to
the national economy, allied industries are worth an estimated $300 M p.a., and the fruit
industry supports over 15,000 full-time and temporary jobs. There is no difference in the
impact of quarantine and non-quarantine MB on the environment. An environmental impact
analysis is therefore warranted on the use of MB for importing strawberry fruit from countries
that still use MB for soil disinfestation, compared with the small amounts currently used in
Victorian strawberry nurseries to support the health and viability of the national industry.
8.5 Recommendations to HIA Limited:
8. This project has demonstrated that great benefits for the whole of the strawberry industry can
occur from research and development applied at a regional level (i.e. Toolangi Victoria). This
project was funded through industry voluntary contributions matched by government money.
The new funding structure of HIA Limited may present a challenge in the future because there
is no longer a clear pathway to support industry-specific research through matched voluntary
contributions, especially at a regional level. The future funding of research projects that are
regionally significant, but have wider impacts, requires further consideration by the strawberry
industry and HIA Limited.
The chemicals Pic, MS, Daz and 1,3-D/Pic (100:0, 65:35, 40:60 and 20:80) are currently registered
for use as pre-plant treatments for soils in Australia. The chemical MB/Pic is currently registered for
47
use as a pre-plant treatment for soil to holders of a critical-use permit or for approved quarantine
uses. The chemicals fluazifop-p and chlorthal-dimethtyl are currently registered for use in
strawberry crops. None of the other chemicals used in this project are currently registered for use
in strawberry runner production in Australia. The up-to-date list of registered products and permits
for strawberry runner production is available on the Australian Pesticide and Veterinary Medicine
Authority (AVPMA) website (http://www.apvma.gov.au).
48
9. Scientific Refereed Publications
Mattner, S.W., Horstra, C.B., Milinkovic, M., Merriman, P.R., Greenhalgh, F.C., 2016. Evaluation of soil-
less systems for strawberry transplant production. Acta Horticulturae (in press).
Mattner, S.W., Milinkovic, M., Merriman, P.R., Porter, I.J., 2014. Critical challenges for the phase-out of
methyl bromide in the Australian strawberry industry. Acta Horticulturae 1044, 367-373.
Mattner, S.W., Porter, I.J., Falco, J., 2014. Recaptured quarantine methyl bromide: An alternative to
methyl bromide for soil disinfestation. Acta Horticulturae 1044, 384-388.
Milinkovic M., Mattner S.W., House, L.T., Greenhalgh, F.C., 2016. Performance of soil-less systems for
strawberry transplant production in Australia. Acta Horticulturae (in submission).
Villalta O.N., Mattner, S.W., et al., 2016. The concentration of 2-propenyl glucosinolate in biofumigant
crops influences the anti-fungal activity (in-vitro) against soil-borne pathogens. Journal of Agricultural
Chemistry and Environment 5, 38–45.
49
10. Intellectual Property/Commercialisation
No commercial IP generated.
50
11. References
Anon. 2010. Marathon runners: The story of the Victorian strawberry runner certification scheme.
VSICA, Melbourne.
BS01004. Identification of sustainable soil disinfestation options for the temperate Australian strawberry
industry. Horticulture Australia Limited, Final Report (2005), Sydney, NSW.
BS04009. Breaking the critical-use barriers preventing Australian horticulture from phasing out methyl
bromide. Horticulture Australia Limited Final Report (2008), Sydney, NSW.
BS06029. Development and design of a soil-less system for production of strawberry runners.
Horticulture Australia Limited, Final Report (2009), Sydney, NSW.
BS07014. Maintaining biosecurity standards for soilborne pathogens and weeds in the strawberry runner
industry. Horticulture Australia Limited, Final Report (2012), Sydney, NSW.
BS09019. Development of a soil-less system for production of strawberry runners. Horticulture Australia
Limited, Final Report (2010), Sydney, NSW.
BS98004. Best practice cropping strategies as alternatives to pre-plant fumigation with methyl bromide
in the temperate Australian strawberry industry. Horticulture Australia Limited, Final Report (2001),
Sydney, NSW.
Fennimore S.A., and Richard, S.J. 1999. Weed control in California strawberries without methyl bromide.
Proceedings of the International MBAO Conference, pp 12: 1-4.
Jennings KM, Monks, DW, Mitcham WE (2006) Weed control options for strawberries on plastic.
Horticulture Information Leaflet 205-B, NC State University.
Lieten P (2013) Advances in strawberry substrate culture during the last twenty years in the Netherlands
and Belgium. International Journal of Fruit Science 13: 84-90.
Mattner SW, Milinkovic M, Merriman PR, Porter IJ (2014) Critical challenges for the phase-out of methyl
bromide in the Australian strawberry industry. Acta Horticulturae 1044: 367-373.
Mattner, SW, Horstra CB, Milinkovic M, Merriman PR, Greenhalgh FC (2016) Evaluation of soil-less
systems for strawberry transplant production. Acta Horticulturae (in press).
Mattner, S.W., Porter, I.J., Gounder, R.K. and Shanks, A.L. (2003). Phytotoxicity and plant-back – critical
issues in the Australian strawberry industry. Proceedings of the International MBAO Conference, pp 12:
1-4.
Menzel CM, Toldi A (2010) An evaluation of containerised plants for strawberries growing in a
subtropical environment. HortTechnology 12: 545-550.
Menzel CM, Waite GK (2006) The performance of strawberry plugs in Queensland. Acta Horticulturae
708: 217-224.
51
Porter, I.J., Banks, J., Mattner, S.W., and P. Fraser. 2009. Global phaseout of methyl bromide under
the Montreal Protocol: Implications for bioprotection, biosecurity and the ozone layer. In Gisi I., Chet,
I., and M. Gullino (Eds). Recent Developments in Disease Management, Volume I. pp 293-309. Springer,
New York, USA.
Strawberries Australia (2012) Strawberries Australia Inc. strategic investment plan 2012-2017.
Horticulture Australia Limited, Sydney, NSW.
Van Wembeke E (2010) Methods to monitor MITC for phytotoxicity and in the environment. Acta
Horticulturae 883: 199-205
UNEP, 2013. Report of the Technology and Economic Assessment Panel 2013. UNEP, Nairobi.
52
12. Acknowledgements
The project team acknowledges the in-kind support and assistance from growers who hosted trials,
chemical companies (Arkema, BOC, and TriCal), and fumigant contractors (R&R Fumigation Services).
53
13. Appendix
Appendix I: Mattner S.W., et al., 2015. Integrated Weed Control in the Strawberry Runner Industry with
Herbicides and Fumigants. Best Practice Flyer, VSICA, Toolangi, Victoria.
VSICA
Victorian Strawberry Industry Certification Authority (VSICA)
Background Currently, the strawberry runner industry at
Toolangi uses mixtures of methyl bromide (MB)
and chloropicrin (Pic) to control soil‐borne
diseases, weeds and pests. MB is highly effective
for weed control, but the Montreal Protocol has
listed it for phase‐out. Ultimately, the runner
industry at Toolangi will need to use substitute
products for MB/Pic to treat soils.
Previous research shows that many substitute
fumigants do not control weeds as effectively as
MB/Pic. In the future, runner growers may need
to consider co‐application of herbicides and
substitute fumigants to manage weeds.
Figure 1: Symptoms of phytotoxicity in strawberry
plants (cv. Monterey) treated with the pre‐emergent
herbicides Goal® (left) and Sinbar® (right). The pre‐
emergent herbicide Gallery® did not cause
phytotoxicity in strawberry plants in trials at Toolangi.
Pre‐Emergent Herbicides Research in the USA has screened a number of
pre‐emergent herbicides for use in strawberries.
The most promising products from this research
were evaluated in trials at Toolangi in the runner
industry in 2013/14. Herbicides were applied
immediately following planting to soils
previously treated with different fumigants.
Figure 2: Weed emergence in soils treated with
different fumigants and pre‐emergent herbicides in the
strawberry runner industry at Toolangi (2013/14). The
blue dashed line represents weed emergence in soils
treated with the standard MB/Pic treatment.
Figure 3: Strawberry runner yields (cv. Monterey) in
soils treated with different fumigants and herbicides at
Toolangi (2013/14). The blue dashed line represents
runner yields in soils treated with the standard MB/Pic
treatment. Some pre‐emergent herbicides (particularly
Dual® and Sinbar®) caused symptoms of phytotoxicity
and low yields in runner crops. Gallery® was the most
successful pre‐emergent herbicide in the trial for weed
control and high strawberry yields.
INTEGRATED WEED CONTROL IN THE STRAWBERRY RUNNER INDUSTRY WITH HERBICIDES AND FUMIGANTS
VSICA
Victorian Strawberry Industry Certification Authority (VSICA)
Most of the pre‐emergent herbicides tested
caused phytotoxicity, stunting, and/or poor
runner yields of strawberry plants (Figure 1). The
herbicide Gallery® (isoxaben), however,
improved weed control and increased
strawberry yields. Co‐application of Gallery® and
the fumigant TF‐80® (20% 1,3‐dichloropropene
(1,3‐D): 80% Pic) and PicPlus® gave equivalent
weed control and runner yields to MB/Pic
(Figure 2 & 3).
Post‐Emergent Herbicides Runner growers in the Netherlands use regular
applications of post‐emergent herbicides, such
as Betanal® (phenmedipham) and Fusilade®
(fluazifop‐p‐butyl), for weed control. Trials were
conducted at Toolangi in 2014/15 to evaluate the
use of pre‐ and post‐emergent herbicides with
substitute fumigants for weed control.
Post‐emergent herbicides were applied to
strawberry runners on a fortnightly basis.
Figure 4: Application of the granular fumigant dazomet
(left), and the liquid fumigant metham sodium (right) in
the runner industry at Toolangi. These fumigants have
strong herbicidal properties and can be co‐applied with
other fumigants (e.g. TF‐80®) for improved weed
control. Dazomet and metham sodium have long
residual times in soils at Toolangi and would require
application well before planting (late summer – early
autumn) to ensure crop safety.
Figure 5: Weed emergence in soils treated with
different fumigants and pre‐ and post‐emergent
herbicides in the strawberry runner industry at
Toolangi (2014/15). The ‘Herbicide Combination’
included Gallery® pre‐emergent, and Betanal® and
Fusilade® post‐emergent treatments. The blue dashed
line represents weed emergence in soils treated with
the standard MB/Pic treatment.
Figure 6: Strawberry runner yields (cv. San Andreas) in
soils treated with different fumigants and pre‐ and
post‐emergent herbicides at Toolangi (2014/15). The
‘Herbicide Combination’ included Gallery® pre‐
emergent, and Betanal® and Fusilade® post‐emergent
treatments. The blue dashed line represents runner
yields in soils treated with the standard MB/Pic
treatment.
Results showed that post‐emergent herbicides
controlled weeds compared with no application
of herbicides. They caused some symptoms of
phytotoxicity to strawberry plants, but did not
reduce their yields. Co‐application of pre‐ and
post‐emergent herbicides gave no better weed
VSICA
Victorian Strawberry Industry Certification Authority (VSICA)
control than pre‐emergent herbicides applied
alone (Figure 5). Co‐application of herbicides
with TF‐80® gave equivalent runner yields and
weed control to MB/Pic (Figures 5, 6 & 8).
Co‐Application of Fumigants Some substitute fumigants to MB/Pic, such as
metham sodium and dazomet (methyl
isothiocyanate (MITC) generators) have
herbicidal properties (Figure 4). Trials at
Toolangi investigated co‐application of MITC
generators with other substitute fumigants.
Results showed that co‐application of metham or
dazomet with TF‐80® or PicPlus® improved weed
(Figures 2 & 5) and soil‐borne pathogen control.
However, metham and dazomet had very long
residual times in soil at Toolangi (3 months), and
caused significant yield losses in strawberry
runners (Figures 3 & 6). This means that growers
would need to apply these products early
(late summer – early autumn), and measure
MITC levels in soil before planting (Figure 7) to
minimise the risk of phytotoxicity with this
approach.
Note: MITC generators are highly reactive when
mixed with many substitute fumigants. This
means they must be applied in separate
operations for safety reasons.
Conclusions The ultimate withdrawal of MB/Pic and the lower
effectiveness of substitute fumigants means that
runner growers will need additional methods to
manage weeds. This will require greater
consideration of cropping rotations
(e.g. biofumigant crops), herbicide treatments
during fallow periods, and the possible
co‐application of herbicides and substitute
Figure 7: Measuring residues of dazomet and metham
sodium in soil using Gastec® tubes.
fumigants before and during runner production.
Results from trials at Toolangi showed that co‐
application of the pre‐emergent herbicide
Gallery® and TF‐80® provided good weed control
and runner yields. These products, however, are
not currently registered for use on strawberry
runners. Chemical companies are using data
from trials at Toolangi to support possible
registration or permits for these products.
Scientific and commercial trials evaluating the
co‐application of substitute fumigants and
herbicides in the runner industry are continuing
at Toolangi.
Many of the chemicals used in these experiments
are not presently registered for use on
strawberry plants in Australia. The list of
registered products and permits for strawberry
runner and fruit production are available on the
APVMA website (www.apvma.com.au). The
product label is the official authority and should
always be followed in relation to the use of a
chemical.
Acknowledgements This work has been funded by Horticulture
Innovation Australia Limited using voluntary
VSICA
Victorian Strawberry Industry Certification Authority (VSICA)
contributions from the Toolangi Certified
Strawberry Runner Growers Co‐operative and
the Victorian Strawberry Industry Certification
Authority with matching funding from the
Australian Government.
Disclaimer Victorian Strawberry Industry Certification Authority
(VSICA) makes no representations and expressly
disclaims all warranties (to the extent permitted by
law) about the accuracy, completeness, or currency of
information in “Integrated Weed Control in the
Strawberry Runner Industry with Herbicides and
Fumigants”.
Reliance on any information provided by VSICA is
entirely at your own risk. VSICA is not responsible for,
and will not be liable for, any loss, damage, claim,
expense, cost (including legal costs) or other liability
arising in any way (including from VSICA or any other
person’s negligence or otherwise) from your use or
non‐use of “Integrated Weed Control in the
Strawberry Runner Industry with Herbicides and
Fumigants”, or from reliance on information
contained in the material or that VSICA provides to
you by any other means.
For further information contact Dr Scott Mattner from VSICA (swmattner@hotmail.com).
Figure 8: Weed emergence and strawberry runner growth (cv. San Andreas) in selected plots treated with different
fumigants and herbicides in a field trial at Toolangi (2014/15).
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